KR102322358B1 - Vibration control unit having hanger bolt - Google Patents

Abstract

The present invention provides a vibration damping device having hanger bolts, wherein common parts are used in a symmetrical manner to reduce manufacturing costs, each part can be assembled easily, and the device can be installed easily using hanger bolts. The vibration damping device having hanger bolts according to an appropriate embodiment of the present invention comprises: a connecting holder having a first cylindrical sleeve and a second cylindrical sleeve formed at both ends respectively, and a pair of connecting rods for connecting the first cylindrical sleeve and the second cylindrical sleeve at both sides; a first hanger bolt having, at one end, a first connecting ring to be connected to one point of a beam-column junction part, and, at the other end, a first shaft inserted into the first cylindrical sleeve of the connecting holder to be able to slide; a pair of first elastic means arranged at both sides of the first cylindrical sleeve respectively while being inserted into the first hanger bolt to absorb seismic energy by being compressed and repelling depending on the moving motion of the first hanger bolt in an axial direction; a second hanger bolt having, at one end, a second connecting ring to be connected to another point of the beam-column junction part, and, at the other end, a second shaft inserted into the second cylindrical sleeve of the connecting holder to be able to slide; and a pair of second elastic means arranged at both sides of the second cylindrical sleeve respectively while being inserted into the second hanger bolt to absorb seismic energy by being compressed and repelling depending on the moving motion of the second hanger bolt in an axial direction.

Description

Vibration control unit having hanger bolt

The present invention relates to a vibration damping device installed in a structure and used to dissipate seismic energy. In particular, it is possible to reduce manufacturing cost by using common parts in a symmetrical structure, and it is easy to assemble each part as well as to use a hanger bolt. It relates to a vibration damping device having a hanger bolt for easy installation.

In general, a vibration damping device is installed in order to improve the seismic performance of a steel frame or a reinforcing bar structure. The vibration damping device reduces the deformation occurring in the structure by absorbing the seismic energy flowing into the structure by the energy dissipation action. Since the vibration damping device dissipates the energy due to deformation, it is installed where the displacement of the structure occurs greatly, and is used for the purpose of increasing the damping. Unlike the seismic isolator, which reduces the response of the structure by lengthening the period of the structure by reducing the response of the structure such as displacement and acceleration, the increase in damping can have a sufficient effect even in high-rise structures and contribute to the improvement of habitability.

As a background technology of the present invention, Korean Patent Registration No. 10-1398365 (Patent Document 1) has been proposed. This provides a friction type energy dissipation device using a disk spring that absorbs and dissipates vibration energy in response to both compression and tension in the axial direction. However, in the background art, since each assembly part has an asymmetric structure, there is only a disk spring that can be used in common, so the number of parts to be manufactured increases, and thus, there is a limit in reducing the manufacturing cost.

As the background technology of the present invention, as Korean Patent Registration No. 10-1093474 (Patent Document 2), 'a vibration damper having a damping force according to an amplitude' is proposed. The background art has the advantage of making the stroke of the piston rod as large as possible, but has a disadvantage in that the structure is complicated and the number of parts is added.

Korean Patent Registration No. 10-1398365 Korean Patent Registration No. 10-1093474

The purpose of the present invention is to provide a vibration damping device having a hanger bolt that can reduce manufacturing cost by using common parts in a symmetrical structure, and facilitates assembly of each part and facilitates installation by the hanger bolt. have.

A vibration damping apparatus having a hanger bolt according to a preferred embodiment of the present invention has a first cylindrical sleeve and a second cylindrical sleeve respectively formed at both ends, and a pair of connecting rods for connecting the first cylindrical sleeve and the second cylindrical sleeve on both ends. a connecting holder; a first hanger bolt having a first connecting ring at one end for being connected to one place of the beam-column joint and a first shaft having a first shaft slidably inserted into the first cylindrical sleeve of the connecting holder at the other end; a pair of first elastic means inserted into the first hanger bolt and disposed on both sides of the first cylindrical sleeve to absorb seismic energy by compressing and repulsing according to the axial movement of the first hanger bolt; a second hanger bolt having a second connecting ring at one end for being connected to another part of the beam-column joint and a second shaft having a second shaft slidably inserted into the second cylindrical sleeve of the connecting holder at the other end; and a pair of second elastic means which are respectively disposed on both sides of the second cylindrical sleeve while being inserted into the second hanger bolt to absorb seismic energy by compressing and repulsing according to the axial movement of the second hanger bolt. do it with

In addition, the pair of first elastic means and the pair of second elastic means is characterized in that it is composed of a coil spring.

In addition, the pair of first elastic means and the pair of second elastic means are characterized in that it is composed of a plate spring.

In addition, a pair of first compression nuts are spaced apart from each other to adjust the compression amount of the pair of first elastic means to the first hanger bolt and are respectively fastened to the threaded portion of the first shaft, any one of the first compression nuts is It is inserted between the pair of connecting rods, characterized in that it is installed so that rotation is suppressed.

In addition, a pair of second compression nuts are spaced apart from each other to adjust the compression amount of the pair of second elastic means to the second hanger bolt and are respectively fastened to the threaded portion of the second shaft, any one of the second compression nuts It is inserted between the pair of connecting rods, characterized in that it is installed so that rotation is suppressed.

In addition, the connecting holder is characterized in that the third elastic means comprising a coil spring or a plate spring positioned between the first and second hanger bolts to increase the compressive and repulsive force is additionally installed.

According to the vibration damping apparatus having a hanger bolt of the present invention, when an earthquake occurs, the first and second hanger bolts installed on both sides of the connecting holder repeatedly pull and push each other in the uniaxial direction, and at the same time compress the elastic means to obtain an earthquake load. By absorbing and dissipating the energy, the deformation of the structure is reduced and the seismic performance is improved.

In addition, since they are installed with a structure symmetrical to each other based on the center of the connecting holder, other parts are used in common, thereby reducing manufacturing costs and facilitating assembly of each part.

In addition, since hanger bolts that can be pivotally coupled to both sides of the connecting holder are provided, it provides the advantage of easy installation of the vibration damping device in the structure.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical spirit of the present invention together with the detailed description of the present invention, so the present invention is limited to the matters described in the accompanying drawings It should not be construed as being limited.
1 is a perspective view of a vibration damping apparatus having a hanger bolt according to an embodiment of the present invention;
Figure 2 is an exploded perspective view of Figure 1;
Figure 3a is an assembly cross-sectional view of Figure 1;
3b and 3c are views of the operating state according to the moving direction of the hanger bolts in FIG. 1;
FIG. 4 is a state diagram in which a third elastic means is added to the vibration damping device of FIG. 1;
5 is a view illustrating various examples in which the vibration damping device shown in FIG. 1 is installed on a structure.
Figure 6 is a state diagram in which the plate spring is installed in place of the coil spring in Figure 3a.

Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the accompanying drawings, but the presented embodiments are illustrative for a clear understanding of the present invention, and the present invention is not limited thereto.

The vibration damping device 10 of the present invention is installed at the beam 101-pillar 102 junction of the structure 100 as shown in FIG. 5 to absorb and dissipate seismic energy. The vibration damping device 10 may be applied to, for example, a steel structure or a reinforced concrete structure.

1 to 3, the vibration damping device 10 includes a connecting holder 12, a first hanger bolt 14, a pair of first elastic means 16a, 16b, a second hanger bolt 18, and a pair of the second elastic means (20a, 20b).

The connecting holder 12 is a pair of connecting connecting the first cylindrical sleeve 121 and the second cylindrical sleeve 122 respectively formed at both ends, and the first cylindrical sleeve 121 and the second cylindrical sleeve 122 on both sides. It has rods 123 and 123 . Therefore, between the pair of connecting rods 123 and 123, a gap G is formed in which a first compression nut 15b and a second compression nut 19b, which will be described later, are fitted.

The first hanger bolt 14 has a first connecting ring 141 for pivotally connected to one place of the beam-column joint at one end and is attached to the first cylindrical sleeve 121 of the connecting holder 12 at the other end. It is slidably inserted and has a first shaft 142 . Accordingly, in the first hanger bolt 14 , the first shaft 142 is axially movably inserted into the first cylindrical sleeve 121 of the connecting holder 12 . The first connecting ring 141 may be installed by being pivotally connected to the structure through a conventional bolt.

The pair of first elastic means 16a and 16b may be configured as a compression spring or as a plate spring as shown in FIG. 6 . The pair of first elastic means 16a and 16b are respectively disposed on both sides of the first cylindrical sleeve 121 at the same time as being inserted into the first hanger bolt 14 to prevent the first hanger bolt 14 from moving in the axial direction. It is installed with compression and repulsion. Therefore, when the first hanger bolt 14 is pulled in FIG. 3B , the compression spring, which is the first elastic means 16a located at the end side, compresses and repulses, and on the contrary, as shown in FIG. 3C , when the first hanger bolt 14 pushes in, the inner side The compression spring, which is the located first elastic means (16b), absorbs and dissipates seismic energy while compressing and repulsing.

The second hanger bolt 18 has a second connecting ring 181 for being connected to another part of the beam-column joint at one end and sliding on the second cylindrical sleeve 122 of the connecting holder 12 at the other end. It has a second shaft 182 possibly inserted therein. Accordingly, the second hanger bolt 18 is axially movably inserted into the second cylindrical sleeve 122 of the connecting holder 12 with the second shaft 182 . The second connecting ring 181 may be installed by being pivotally connected to the structure through a conventional bolt.

The pair of second elastic means 20a and 20b are respectively disposed on both sides of the second cylindrical sleeve 122 at the same time as being inserted into the second hanger bolt 18 to prevent the second hanger bolt 18 from moving in the axial direction. It is installed so as to rebound by compression. The pair of second elastic means 20a and 20b may be composed of a compression spring as shown in FIG. 3A or a plate spring as shown in FIG. 6 .

Therefore, when the second hanger bolt 18 is pulled in FIG. 3B , the compression spring, which is the second elastic means 20a located at the end side, compresses and repulses, and on the contrary, when the second hanger bolt 18 pushes in, the second elastic located inside The compression spring, which is the means (20b), absorbs and dissipates seismic energy while compressing and repulsing.

Meanwhile, in the first hanger bolt 14 , a pair of first compression nuts 15a and 15b are spaced apart from each other to adjust the amount of compression of the pair of first elastic means 16a and 16b, and the first shaft 142 is spaced apart from each other. ) is fastened to the screw portions 142a and 142b, respectively, and any one of the first compression nuts 15b is inserted between the pair of connecting rods 123 and 123 to suppress rotation.

In addition, in the second hanger bolt 18 , a pair of second compression nuts 19a and 19b are spaced apart from each other to adjust the amount of compression of the pair of second elastic means 20a and 20b, and the second shaft 182 ) are respectively fastened to the screw portions 182a and 182b, and any one of the second compression nuts 19b is inserted between the pair of connecting rods 123 and 123 to suppress rotation.

When the pair of first compression nuts 15a and 15b and the second compression nuts 19a and 19b are installed in this way, the first hanger bolt 14 and the second hanger bolt 18, the first compression nut 15a, 15b) and the advantage of being able to adjust the position at which the first elastic means 16a, 16b and the second elastic means 20a, 20b can optimally compress and rebound by rotating the second compression nut 19a, 19b. has

As shown in FIG. 5 , the vibration damping device 10 configured in this way is installed in various states at the beam-column junction of the structure 100, and when an earthquake load is generated due to an earthquake, the first hanger bolt 14 ) and the second hanger bolt 18 are repeatedly compressed by compressing the first elastic means 16a, 16b and the second elastic means 20a, 20b while performing the pulling or pushing in in the axial direction on the same axis. and dissipates seismic energy.

That is, as the first hanger bolt 14 vibrates in the axial direction, the pair of first elastic means 16a and 16b are compressed alternately, and together with the second hanger bolt 18 vibrates in the axial direction, the pair of The second elastic means 20a and 20 are compressed alternately. By repeating this compression process, the seismic load is consumed as compressive energy, thereby dissipating the seismic energy.

On the other hand, the present invention can dissipate greater seismic energy by increasing the compressive repulsive force by additionally installing the third elastic means 30 in the connecting holder 12 as shown in FIG. 4 . The third elastic means 30 may be composed of a coil spring or a plate spring. At this time, the third elastic means 30 is installed between the first hanger bolt 14 and the second hanger bolt 18 .

As described above, according to the vibration damping device 10 of the present invention, when an earthquake occurs, the first hanger bolt 14 and the second hanger bolt 18 installed on both sides of the connecting holder 12 move in the axial direction while moving in the axial direction. By pressing the first elastic means (16a, 16b) and the other pair of second elastic means (20a, 20b) to absorb and dissipate the seismic load, the seismic performance of the structure is improved.

In addition, since they are installed with a symmetrical structure based on the center of the connecting holder 12, other parts except for the connecting holder 12 are used in common, thereby reducing manufacturing cost and easy assembly of each part. .

In addition, the first hanger bolt 14 and the second hanger bolt 18 connected to both sides of the connecting holder 12 provide an advantage that can be installed to the structure through a normal bolt.

So far, the present invention has been described in detail with reference to the presented embodiments, but those skilled in the art can make various modifications and modified inventions without departing from the technical spirit of the present invention with reference to the presented embodiments. will be. The present invention is not limited by such variations and modifications, but only by the claims appended hereto.

10: vibration damping device
12: connecting holder
14: first hanger bolt
16a, 16b: first elastic means
18: second hanger bolt
20a, 20b: second elastic means
30: third elastic means

Claims (6)

In the vibration damping device (10) installed at the beam-column junction of the structure,
Having a pair of connecting rods 123 and 123 for connecting the first cylindrical sleeve 121 and the second cylindrical sleeve 122 respectively formed at both ends, and the first cylindrical sleeve 121 and the second cylindrical sleeve 122 on both sides a connecting holder 12;
A first shaft having a first connecting ring 141 for being connected to one place of the beam-column joint at one end and slidably inserted into the first cylindrical sleeve 121 of the connecting holder 12 at the other end ( a first hanger bolt 14 having 142;
A pair of pairs that are respectively disposed on both sides of the first cylindrical sleeve 121 at the same time as being inserted into the first hanger bolt 14 to compress and rebound according to the axial movement of the first hanger bolt 14 to absorb seismic energy. The first elastic means (16a, 16b) and;
A second shaft having a second connecting ring 181 for being connected to another part of the beam-column joint at one end and slidably inserted into the second cylindrical sleeve 122 of the connecting holder 12 at the other end. a second hanger bolt (18) having (182);
A pair of pairs that are respectively disposed on both sides of the second cylindrical sleeve 122 at the same time as being inserted into the second hanger bolt 18 to absorb seismic energy by compressing and repulsing according to the axial movement of the second hanger bolt 18 . Including; second elastic means (20a, 20b);
In the first hanger bolt 14 , a pair of first compression nuts 15a and 15b are spaced apart from each other to adjust the amount of compression of the pair of first elastic means 16a and 16b. Each of the screw parts 142a and 142b are fastened to each other, and any one of the first compression nuts 15b is inserted between the pair of connecting rods 123 and 123 to suppress rotation,
In the second hanger bolt 18 , a pair of second compression nuts 19a and 19b are spaced apart from each other to adjust the compression amount of the pair of second elastic means 20a and 20b, and Hanger bolts, characterized in that each fastened to the screw portions (182a, 182b), any one of the second compression nut (19b) is inserted between the pair of connecting rods (123 and 123) is installed so that rotation is suppressed. A vibration damping device with The method of claim 1,
A pair of first elastic means (16a, 16b) and a pair of second elastic means (20a, 20b) is a vibration damping device having a hanger bolt, characterized in that it is composed of a coil spring. The method of claim 1,
A vibration damping device having a hanger bolt, characterized in that the pair of first elastic means (16a, 16b) and the pair of second elastic means (20a, 20b) are formed of a plate spring. delete delete The method of claim 1,
The connecting holder 12 has a third elastic means 30, which is located between the first hanger bolt 14 and the second hanger bolt 18, and consists of a coil spring or a plate spring that increases the compressive and repulsive force is additionally installed. Vibration damping device with hanger bolts.

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